Phagocytosis of latex beads is defective in cultured human retinal pigment epithelial cells with persistent rubella virus infection.

Phagocytosis, a secondary function of retinal pigment epithelial (RPE) cells essential to sight, was significantly decreased, when measured with latex beads, during persistent rubella virus (RV) infection of human cultured RPE cells. A target for RV in vivo, RPE cells infected with RV (RPE/RV) ingested fewer fluorescent microspheres (26%) than did uninfected RPE cells (68%) (P < 0.001), as measured by flow cytometry. In RPE/RV cells, with characteristic RPE monolayer appearance and normal growth during subculturing over 6 months, persistent RV infection was shown by specific RV antigen immunofluorescence, by the presence of the RV genome in RPE/RV cell messenger RNA, and by recovery of cell-free RV after cocultivation with Vero cells. The adhesion of latex beads to apical cell surfaces of RPE/RV and uninfected RPE cells appeared similar, as imaged by scanning electron microscopy. Cytoskeletal actin, a component of phagocytosis in RPE, appeared altered in 60 to 75% of RPE/RV cells by antiactin immunofluorescence staining, as previously described in other RV-infected cells, but its role in the disturbed phagocytosis of latex beads was not determined. Persistently RV-infected human RPE is an additional example of RV-associated secondary cellular dysfunction in the absence of cytopathic effects.     

Stable expression of noncytopathic Kunjin replicons simulates both ultrastructural and biochemical characteristics observed during replication of Kunjin virus

This report focuses mainly on the characterization of a Vero cell line stably expressing the flavivirus Kunjin (KUN) replicon C20SDrep (C20SDrepVero). We showed by immunofluorescence and cryoimmunoelectron microscopy that unique flavivirus-induced membrane structures, termed convoluted membranes/paracrystalline structures, were induced in the C20SDrepVero cells. These induced cytoplasmic foci were immunolabeled with KUN virus anti-NS3 antibodies and with antibodies to the cellular markers ERGIC53 (for the intermediate compartment) and protein disulfide isomerase (for the rough endoplasmic reticulum). However, in contrast to the large perinuclear inclusions observed by immunofluorescence with anti-double-stranded (ds)RNA antibodies in KUN virus-infected cells, the dsRNA in C20SDrepVero cells was localized to small isolated foci scattered throughout the cytoplasm, which were coincident with small foci dual-labeled with the trans-Golgi specific marker GalT. Importantly, persistent expression of the KUN replicons in cells did not produce cytopathic effects, and the morphology of major host organelles (including Golgi, mitochondria, endoplasmic reticulum, and nucleus) was apparently unaffected. The amounts of plus- and minus-sense RNA synthesis in replicon cells were similar to those in KUN virus-infected cells until near the end of the latent period, but subsequently increases of about 10- and fourfold, respectively, occurred in infected cells. Virus-specified protein synthesis in C20SDrepVero cells was also about 10-fold greater than that in infected cells. When several KUN replicon cell lines were compared with respect to membrane induction, the relative efficiencies increased in parallel with increases in viral RNA and protein synthesis, consistent with the increases observed during the virus infectious cycle. Based on these observations, cell lines expressing less-efficient replicons may provide a useful tool to study early events in flavivirus RNA replication, which are difficult to assess in virus infections.     

In situ detection of rubella RNA and antigens in cultured cells

We developed in situ hybridization and immunofluorescent procedures to detect rubella RNA and antigens in tissue-cultured cells infected with rubella virus. cDNA fragments of the rubella virus E1 structural gene were used as probes for in situ hybridization to detect rubella RNA sequences in Vero cells infected with rubella virus. Using antibodies against rubella proteins, indirect immunofluorescence detected rubella virus structural proteins in Vero cells infected with rubella virus. The immunofluorescence method has also been applied to study the expression of rubella polypeptide E1 in transfected COS cells and may be applied to the detection and study of persistent rubella virus infection in human tissues.     

Rubella virus-induced apoptosis varies among cell lines and is modulated by Bcl-XL and caspase inhibitors

Rubella virus (RV) causes multisystem birth defects in the fetuses of infected women. To investigate the cellular basis of this pathology, we examined the cytopathic effect of RV in three permissive cell lines: Vero 76, RK13, and BHK21. Electron microscopy and the TUNEL assay showed that the cytopathic effect resulted from RV-induced programmed cell death (apoptosis) in all three cell lines, but the extent of apoptosis varied among these cells. At 48 h postinfection, the RK13 cell line showed the greatest number of apoptotic cells, the Vero 76 cell line was approximately 3-fold less, and BHK21 had very few. An increased multiplicity of infection and longer time postinfection were required for the BHK21 cell line to reach the level of apoptotic cells in Vero 76 at 48 h. Purified RV induced apoptosis in a dose-dependent fashion, but not UV-inactivated RV or virus-depleted culture supernatant. Specific inhibitors of the apoptosis-specific proteases caspases reduced RV-induced apoptosis and led to higher levels of RV components in infected cells. To address the role of regulatory proteins in RV-induced apoptosis, the antiapoptotic gene Bcl-2 or Bcl-XL was transfected into RK13 cells. Although a high level of Bcl-2 family proteins was expressed, no protection was observed from apoptosis induced by RV, Sindbis virus, or staurosporine in RK13 cells. In BHK21 cells, however, increased expression of Bcl-XL protected cells from apoptosis. The observed variability in apoptotic response to RV of these cell lines demonstrates that programmed cell death is dependent on the unique properties of each cell and may be indicative of how selective organ damage occurs in a congenital rubella syndrome fetus.     

In situ hybridization for quantitative assay of infectious hepatitis A virus.

A method of in situ hybridization using single-stranded RNA probes of opposite polarity for quantitative enumeration of hepatitis A virus (HAV) in infected cells has been developed. Kinetic experiments showed that foci of infected cells appeared as early as day 2 postinfection. The absence of foci in cells examined immediately after virus adsorption indicated that foci detected subsequently were related to viral replication. Foci were detected by hybridization with RNA probes complementary to HAV genomic RNA but not with RNA probes identical to HAV genomic RNA. The number of foci observed was linearly related to the HAV dose inoculated. Focus formation was reduced when a virus inoculum was pretreated with guinea pig anti-HAV hyperimmune serum but not when it was pretreated with preimmune serum. The high resolution of hybridization signals and relative rapidity of the test indicated that this technique will be useful for measuring serum neutralizing antibodies and for quantitative assay of infectious HAV.     

In vitro detection of canine distemper virus nucleic acid with a virus-specific cDNA probe by dot-blot and in situ hybridization

A cDNA library was prepared from canine distemper viral (CDV) messenger RNA (mRNA) derived from Vero cells lytically infected with the Onderstepoort strain (Ond) of CDV. A 300 base pair insert was identified which, by Northern blot analysis and Sanger sequence data, was shown to be specific to the nucleocapsid gene. The nucleocapsid (NC) clone was radiolabelled with 32P using nick translation and used to detect viral RNA in both dot-blot and in situ preparations of Vero cells lytically infected with Onderstepoort CDV (Ond-CDV) and immortalized mink lung cells persistently infected with racoon origin CDV (CCL64-RCDV). Dot-blot hybridization results paralleled immunofluorescent results in the lytically infected cells. In 18 persistently infected cell lines from the RCDV-CCL64 parental stock, 13 lines were positive and two were negative on both immunofluorescence and dot-blot hybridization analysis for CDV antigen and RNA, respectively. Viral nucleic acid was detected in these persistently infected cells, where as few as 1.9% of the members of a line were positive on immunofluorescence. A dot-blot autoradiographic signal was obtained in three lines which were negative for CDV antigen. CDV RNA was detected in both lytically and persistently infected cell lines by in situ hybridization, where decreasing probe length was important in increasing the sensitivity of this assay. Viral RNA was detected in over 90% of the lytically infected cells, where only 70% were positive for viral antigen by immunofluorescence.     

Rubella virus infection dysregulates the pattern of p63 expression

The effect of rubella virus (RV) on the expression of the p63 isoforms was investigated in Vero cells. The levels of all the TAp63 isoforms were elevated, while the expression of a approximately 73 kDa isoform corresponding to DeltaNp63alpha was downregulated in Vero cells infected with the To-336 strain of RV. A approximately 66 kDa isoform corresponding to TAp63beta was the predominant protein species in RV-infected cells. Semi-quantitative end-point dilution RT-PCR analysis, with TAp63beta isoform-specific primers, detected a 4-fold rise in the TAp63beta mRNA level following virus infection. Taken together, our data demonstrate that RV infection alters the stoichiometric ratio of the p63 isoforms. The dysregulated pattern of p63 expression observed in RV-infected cells may represent a mechanism whereby RV exerts its pro-apoptotic effect.     

Rubella virus nonstructural protein 2 is a minor immunogen

The full-length nonstructural protein P90 of rubella virus (RV) was expressed as recombinant protein in Escherichia coli bacteria, as well as in Vero cells. Monoclonal antibodies raised against the protein specifically reacted with the protein in both P90-transfected and RV infected Vero cells. Ninety human sera obtained from reconvalescents, vaccinees and patients with acute RV infection were tested for reactivity against the P90 protein. A weak immune reaction was detected only in a small minority (8%), indicating that P90 is minor immunogen for RV and is not suitable for diagnostic purposes.     

Cultivation of Ehrlichia chaffeensis in mouse embryo, Vero, BGM, and L929 cells and study of Ehrlichia-induced cytopathic effect and plaque formation.

We successfully propagated Ehrlichia chaffeensis in mouse embryo, Vero, BGM, and L929 cells inoculated with host cell-free ehrlichiae, indicating that E. chaffeensis is capable of entry, survival, and growth in a relatively wide range of cell types derived from different species. We demonstrated rapid adaptation of E. chaffeensis in these cell lines, so that typical morulae could be detected as early as 5 days after inoculation. E. chaffeensis-induced cytopathic effect with different morphological characteristics in mouse embryo, Vero, and L929 cells. The earliest cytopathic effect appeared in untreated and irradiated mouse embryo cells at 4 days postinoculation. As the infected foci gradually expanded, the center of the foci showed necrotic cells with pyknotic nuclei and degraded morulae. E. chaffeensis caused cell lysis in untreated and irradiated L929 cells, with formation of distinct, round macroscopic plaques at 18 days postinoculation. In untreated and irradiated Vero cells, E. chaffeensis produced infected foci composed of loosely interwoven necrotic cells, spaces of detached cells, cells filled with morulae, and uninfected cells, resulting in characteristic reticular foci. Irradiated cells generally contained many large morulae and presented larger cytopathic foci. DH82 and BGM cells did not develop obvious cytopathic foci under the conditions employed. The findings reported herein offer the opportunity to study the pathogenic mechanism of cell injury by E. chaffeensis, the basis for quantification of infectious E. chaffeensis, improved approaches for recovery of ehrlichiae from human patients and tick hosts, and additional methods for cultivation of E. chaffeensis for molecular analysis.     

Adaptation of transmissible gastroenteritis virus to growth in non-permissive Vero cells

Summary The CPK cells derived from swine kidney were infected with the attenuated TO-163 strain of transmissible gastroenteritis (TGE) virus, and fused with uninfected Vero cells in the presence of polyethylene glycol. Repeated cocultivation of the fused cells with uninfected Vero cells rendered the virus to grow in Vero cells. The Vero cell-adapted virus acquired the ability to infect and produce cytopathic effects in several other non-permissive cell lines of non-porcine origin. No major differences in viral polypeptides were shown between the Vero cell-adapted TO-163 strain and its parent strain by indirect immunofluorescence and Western blotting using monoclonal and polyclonal antibodies to TGE virus.     

Variation in distribution of the three flavivirus-specified glycoproteins detected by immunofluorescence in infected Vero cells

Summary Indirect immunofluorescence with rabbit antisera was used to probe the intracellular locations of the antigens of envelope, prM (precursor to structural protein M) and the nonstructural glycoproteins NS 1 (formerly described as NV 3 or SCF) specified by the flaviviruses dengue-2 and Kunjin. Perinuclear staining in various types of foci was prominent for all antigens, and the distribution was influenced by whether cells were fixed with acetone or formaldehyde. Staining of Golgi-like masses or inclusions by anti-envelope sera occurred regularly and prominently in cells infected and stained with homologous anti-envelope antibodies; in the cross reactions, such staining was largely absent, especially in dengue-2 infected cells in which it was replaced by many small circular foci scattered throughout the cytoplasm. Anti-NS 1 also stained large perinuclear inclusions and small cytoplasmic foci, but the distribution of these was dissimilar to that observed with anti-envelope sera. Anti-prM appeared to contain a mixture of antibodies of different specificities, evident at different dilutions, possibly because of different cytoplasmic locations of prM and its cleavage products. All antisera produced small discontinuous foci on the plasma membrane of unfixed infected cells; antigens of NS 1 were sometimes prominent on the surface of acetone-fixed cells.With 5 Figures     

siRNA抑制SARS冠状病毒感染Vero E6细胞

目的　用RNA干扰技术特异性抑制SARS冠状病毒在非洲绿猴肾细胞VeroE6中的增殖。方法　体外转录合成针对SARS CoVRNA的siRNA ,使用脂质体转染的方法导入细胞 ,观察并估算病毒感染细胞病变值 ,MTT法检测细胞存活率 ,RT PCR确定胞内病毒RNA水平。结果　成功筛选出 4组siRNA能够显著降低SARS CoV感染细胞中病毒RNA水平 ,提高感染细胞存活率。结论　应用RNAi技术可以有效阻止病毒在细胞中增殖 ,为治疗病毒性疾病提供了新思路。     

Time course of virus-specific macromolecular synthesis during rubella virus infection in Vero cells

Virus specific macromolecular synthesis was studied in Vero cells infected with plaque-purified rubella virus under one-step multiplication conditions. Under these conditions, the rate of virus production was found to increase rapidly until 24 hr postinfection after which time the rate of virus production rose more slowly, reaching a peak level at 48 hr postinfection. This peak rate of virus production was maintained through 72 hr postinfection. A majority of the cells remained alive through 96 hr postinfection, although a 20 to 30% decrease in the number of living cells occurred between 24 and 48 hr postinfection, the time period at which cytopathic effect was first observed. The virus structural proteins were first detected intracellularly at 16 hr postinfection. The rate of synthesis of these proteins was already maximal at 16 hr postinfection and remained constant through 48 hr postinfection. By immunofluorescence, cells expressing virus proteins were first observed at 12 hr postinfection. At 24 hr postinfection, 35 to 50% of the cells in the infected culture were exhibiting immunofluorescence, at 36 hr postinfection, 65 to 90% of the cells were exhibiting immunofluorescence, and at 48 hr postinfection, all of the cells were exhibiting immunofluorescence. The virus genomic and subgenomic RNA species were first detectable by 12 hr postinfection. The rate of synthesis of both of these species peaked at 26 hr postinfection. Rubella virus infection was found to have no effect on total cell RNA synthesis. However, a modest inhibition of total cell protein synthesis which reached 40% by 48 hr postinfection was observed. When Northern analysis of RNA extracted from infected cells was performed, a negative-polarity, virus-specific RNA probe hybridized only to the virus genomic and subgenomic RNA species. A positive-polarity, virus-specific RNA probe hybridized predominantly to a negative-polarity RNA of genome length indicating that both the genomic and subgenomic RNAs are synthesized from a genome-length negative-polarity template. Defective interfering (DI) RNAs were not detected in infected cells through 96 hr postinfection or in cells onto which virus released through 96 hr postinfection was passaged. Thus, the generation of DI particles by rubella virus appears to play no role in the slow, noncytopathic replication of this virus or in the ability of rubella virus-infected cells to survive for extended periods of time.     

Rhinovirus type 14 persistence in HeLa cells studied by use of guanidine.

Guanidine at 2 mM completely prevents replication of rhinovirus type 14 (RV14) in HeLa cells and spares these cells from RV14-induced cytopathic effects. Three serial subcultivations of these cells in the continued presence of guanidine reduced infectious virus titers in cell lysates to undetectable levels. However, the capacity of RV14-infected guanidine-cultured cells to form infectious centers when cultured in the absence of guanidine was not completely abolished until the fifth serial subcultivation (14 days post-inoculation). Production of defective-interfering particles of RV 14 in HeLa cells was not observed. Thermal stability and transmission of uncoated RV 14 to daughter cells in the presence of guanidine can account for the persistence. Cells inoculated with RV14 and cultured in the presence of guanidine synthesized genomic RNA associated with a structure of 1.394 gm/ml density in CsCI, and these structures exhibited low infectivity by standard plaque assay. Nascent RV14 RNA did not appear in virions in cells treated with guanidine. HeLa cell lines (HeLa_V+G), established following six serial subcultures of cells initially infected with RV 14 and continuously cultured in the presence of guanidine, were negative for RV 14 antigens by specific immunofluorescence tests. HeLa_V+G cells were as efficient as normal HeLa cells in production of interferon; replication of RV 14 and mengovirus; and plaque assay of RV 14, rhinovirus type 2, and coxsackievirus B3.     

Nascent flavivirus RNA colocalized in situ with double-stranded RNA in stable replication complexes.

Incorporation of bromouridine (BrU) into viral RNA in Kunjin virus-infected Vero cells treated with actinomycin D was monitored in situ by immunofluorescence using antibodies reactive with Br-RNA. The results showed unequivocally that nascent viral RNA was located focally in the same subcellular site as dsRNA, the putative template for flavivirus RNA synthesis. When cells were labeled with BrU for 15 min, the estimated cycle period for RNA synthesis, the nascent Br-RNA was not digested in permeabilized cells by RNase A under high-salt conditions, in accord with our original model of flavivirus RNA synthesis (Chu, P. W. G., and Westaway, E. G., Virology 140, 68-79, 1985). The model assumes that there is on average only one nascent strand per template, which remains bound until displaced during the next cycle of RNA synthesis. The replicase complex located by BrU incorporation in the identified foci was stable, remaining active in incorporating BrU or [32P]orthophosphate in viral RNA after complete inhibition of protein synthesis in cycloheximide-treated cells. These results are in accord with our proposal that dsRNA detected in foci previously located by immunofluorescence or by immunogold labeling of induced vesicle packets is functioning as the true replicative intermediate (Westaway et al., J. Virol. 71, 6650-6661, 1997; Mackenzie et al., Virology 245, 203-215, 1998). Implications are that the replicase complex is able to recycle in the same membrane site in the absence of continuing protein synthesis and that possibly apart from uncleaved NS3-NS4A, it has no requirement for a polyprotein precursor late in infection.     

Intercellular spread of Shigella flexneri through a monolayer mediated by membranous protrusions and associated with reorganization of the cytoskeletal protein vinculin.

The spread of Shigella flexneri in a monolayer of infected Henle and HeLa cells was studied by using immunofluorescence and electron microscopy. Infected cells produced numerous bacterium-containing membranous protrusions up to 18 microns in length that penetrated adjacent cells and were subsequently phagocytosed. Fluorescence staining of actin and vinculin in infected cells with phalloidin and monoclonal antibody to vinculin, respectively, demonstrated that the protrusions containing the bacteria consisted of these cytoskeletal proteins. Actin accumulated predominantly at the poles of bacteria distal to the tip of protrusions and appeared as trails extending back towards the host cell cytoplasm. Vinculin, however, was distributed uniformly around the bacteria and throughout the protrusion. A profound rearrangement of vinculin occurred in Henle and HeLa cells following infection with shigellae: whereas in uninfected cells it was distributed mainly around the cell periphery, in infected cells it concentrated mainly around clusters of bacteria in the cytoplasm. This suggests a possible involvement of the vinculin cytoskeletal protein in the intercellular spread of shigellae during an infection.     

Replication complexes associated with the morphogenesis of rubella virus

Summary Thin section electron microscopy was used to investigate cellular changes associated with the replication of rubella virus (RV) in Vero cells and to compare these changes to those of the related alphavirus, Semliki Forest virus (SFV). Conspicuous membrane-bound cytoplasmic vacuoles analogous to the alphavirus replication complexes were observed in RV infected cells but not in mock infected cells. The vacuoles were characterised by membrane-bound vesicles measuring about 60 nm which often displayed an irregular dense core and/or a network of fibres. These vesicles were morphologically distinct from RV particles and were generally located at regular intervals on the inner side of the surrounding membrane of the RV replication complex. Degenerating cellular material was often found in the membrane-bound vacuole of a replication complex. The replication complexes were intimately associated with the rough endoplasmic reticulum (RER), which was localised 45–75 nm from the surrounding membrane of the replication complex. Parallel studies of replication complexes in SFV infected cells did not reveal such an intimate association with the RER. RV replication complexes appeared as early as 8 h post infection (p.i.), before detection of RV particles by electron microscopy, and their peak production at 24 h p.i. coincided with the time of maximum virus titre.     

A persistent infection of Vero cells by egg-adapted mumps virus

Serial subculture of Vero cells infected with the chick embryo adapted Enders strain of mumps virus gives rise to a low level productive though persistent infection. Persistently infected cultures exhibit minimal cytopathology; however, widely dispersed foci of multinucleate cells are almost always present. Neither infected cell nor virus growth is temperature sensitive. Biological and biochemical evidence indicate that defective interfering particles are replicated along with infectious (nondefective) virus during the course of the persistent infection, although the plaque-purified inoculum virus stock contained only genome size RNA. With continued cell passage a heterogeneous, changing population of subgenomic sized viral RNA accumulates, suggesting that defective interfering (DI) RNA species are evolving from virion RNA, with no single DI RNA predominating. Since such factors as interferon, antibody, and temperature-sensitive mutants are absent from this system, DI particles are the likely factor modulating this persistent infection.     

Inhibition of replication of Venezuelan equine encephalomyelitis with polyclonal antibodies to laminin-binding protein

A study of temporal and quantitative characteristics of inhibition of replication of Venezuelan equine encephalomyelitis (VEE) virus, strain TC-83, in Vero and CPE on PK cells showed purified polyclonal rabbit antibodies to human recombinant laminin-binding protein (LBP) to be able to block completely the development of cytopathic effect (CPE) in such cells, when infected with 10(7) CPE60. The extent of VEE infection inhibition in Vero was in direct proportion to a concentration of specific antibodies within a range of 0.44-3 microg/100 microl. When antibodies were added to Vero cells after they were infected, there was a gradual attenuation of the inhibition effect, which stopped almost completely 9 hours after the antibodies were placed. Inhibition was effective at 4 degrees C and 37 degrees C. A lack of synthesis of viral glycoprotein E2 in Vero cells infected in the presence of antibodies to LBP is an extra argument proving that the VEE replication is inhibited at early infection stages. The data obtained demonstrated the general LBP significance for the penetration of VEE into mammalian cells and the related importance of designing new antiviral drugs against alpha-viral infection, which are based on blocking the mechanism of receptor penetration of the virus into the cell.     

Quantitation of flaviviruses by fluorescent focus assay

An indirect immunofluorescence assay for quantitation of flaviviruses was developed as an alternative to the standard plaque assay. The assay was validated with West Nile virus (WNV), St. Louis encephalitis virus (SLEV), and Dengue virus (DENV) types 1-4. Vero cells were plated in 8-well chamber slides, and infected with 10-fold serial dilutions of virus. About 1-3 days after infection, cells were fixed, incubated with specific monoclonal antibody, and stained with a secondary antibody labeled with a fluorescent tag. Fluorescent foci of infection were observed and counted using a fluorescence microscope, and viral titers were calculated as fluorescent focus units (FFU) per ml. The optimal time for performing the fluorescent focus assay (FFA) on Vero cells was 24 h for WNV, and 48 h for SLEV and the four DENV serotypes. In contrast, the time required to complete a standard Vero cell plaque assay for these viruses range from 3 days for WNV to 11 days for DENV-1. Thus, the FFA method of virus titration is useful for viruses whose plaques develop slowly. In addition, these viruses can be quantitated by FFA on a mosquito cell line (C6/36), which does not support plaque formation. The FFA for flaviviruses was validated for accuracy, precision, specificity, and robustness of the assay.